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Simultaneous fluorescence visualization of endoplasmic reticulum superoxide anion and polarity in myocardial cells and tissue Haibin Xiao, Chuanchen Wu, Ping Li, and Bo Tang Anal. Chem., Just Accepted Manuscript • DOI: 10.1021/acs.analchem.7b05440 • Publication Date (Web): 17 Apr 2018 Downloaded from http://pubs.acs.org on April 17, 2018
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Analytical Chemistry
Simultaneous fluorescence visualization of endoplasmic reticulum superoxide anion and polarity in myocardial cells and tissue Haibin Xiao, Chuanchen Wu, Ping Li,* and Bo Tang* College of Chemistry, Chemical Engineering and Materials Science, Collaborative Innovation Center of Functionalized Probes for Chemical Imaging in Universities of Shandong, Key Laboratory of Molecular and Nano Probes, Ministry of Education, Institute of Biomedical Sciences, Shandong Normal University, Jinan 250014, P. R. China *E-mail:
[email protected];
[email protected]. Tel.: +86 531 86180010.
ABSTRACT: Diabetic cardiomyopathy (DCM) is a critical complication of diabetes, the accurate pathogenesis of which remains elusive. It’s widely accepted that endoplasmic reticulum (ER) stress and abnormal fluctuations of reactive oxygen species (ROS) are considered to be closely associated with progress of DCM. In addition, DCM-induced changes of myocardial tissue and ROSderived oxidation of proteins will cause changes of the hydrophilic and hydrophobic domains and may further seriously alter the myocardial cell polarity. Thus, real time detection of ROS and polarity in ER of live cells and in tissue will contribute to revealing the exact molecular mechanisms of DCM. In this article, we firstly present an ER-targetable fluorogenic probe termed ER-NAPC for sensitive and selective detection of superoxide anion (O2•−). ER-NAPC can precisely target ER and visualize the increase of O2•− level in live H9c2 cardiomyocyte cell during ER stress. Meanwhile, by combining ER-NAPC with a polarity-sensitive probe ER-P, we accomplish the simultaneous fluorescence visualization of O2•− and polarity in ER of live cells and diabetic myocardial tissue. The dual-color fluorescence imaging results indicate that the O2•− level and polarity will synergistically rise during ER stress in live cells and diabetic myocardial tissue. The proposed dual-color imaging strategy may offer a proven methodology for studying coordinated variation of different parameters during ER stress oriented disease.
Diabetes mellitus, as a metabolic disease leads to significant morbidity and mortality.1 In particular, diabetic cardiomyopathy (DCM) characterized by cardiac fibrosis is a critical complication of diabetes and a leading cause of death.2,3 The occurrence and development of DCM is a chronic and complicated process that is involved in abnormal cellular metabolism and dysfunctions in organelles, such as myofibrils, mitochondria, and sarcolemma.4-8 Although multiple mechanisms for the progress of DCM have been proposed, including excess oxidative stress, impaired calcium homeostasis, mitochondrial dysfunction and activation of apoptotic signalling pathways, 913 the accurate pathogenesis of DCM remains incompletely understood. When normal functions of the endoplasmic reticulum (ER) was disturbed by various conditions, such as glucotoxicity, ER Ca2+ disequilibrium, ischemia and hypoxia, free radicals, increased protein synthesis, ER stress will appear accompanying production of reactive oxygen species (ROS).14 Recently, a number of studies have demonstrated the crucial role of ER stress and increased ROS in the development of DCM.15-17 For instance, the markers of ER stress are elevated in the hearts of diabetic animals; ROS are contribute to diabetes-induced cardiomyocytes damage, and metallothionein will prevent diabetes-induced deficits in cardiomyocytes by inhibiting ROS production.18,19 Superoxide anion (O2•−), as the most important and first produced ROS, is the precursor of other ROS. The concentration variations of O2•− determine the level of other ROS.20 In addition, on the one hand, DCM will result in many
changes in the microstructure and morphology of myocardial tissue, such as fibrosis, myocardial hypertrophy,21 on the other hand, the overproduction ROS will oxidized the thiolate of protein to sulfenic acid further to sulfinic acid and sulfonic acid,22,23 which probably cause dysfunction of protein secretion and modification as well as changes of hydrophilic and hydrophobic domains, thus might affecting the ER polarity environment.24 Therefore, developing new method for real time detection of O2•− and polarity in ER of live cells and in tissue will contribute to uncovering the exact molecular mechanisms of DCM. Fluorescence imaging is emerging as a promising and powerful means for monitoring various bioactive molecules in living systems, which thanks to its remarkable advantages, such as easy operation, high sensitivity and high temporalspatial resolution.25-37 In particular, due to the distinguishable spectra it can study the synergistic changes of different bioactive species through simultaneous fluorescence detection. However, up to now, although many representative organelletargetable O2•− and polarity responsive fluorescent probes have been presented,38-45 and simultaneous monitoring of multiple species was also reported,46-50 specific sensors suitable for visualization of ER O2•− and further simultaneous fluorescence imaging of ER O2•− and polarity in live cells and tissues haven’t been explored.
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Scheme 1. (a) The structure of ER-NAPC and proposed sensing mechanism for O2•−. (b) The schematic diagram of simultaneous fluorescence visualization of O2•− and polarity in ER.
To solve the above-mentioned problem, it’s an urgent need to develop new method for simultaneous fluorescence imaging of ER O2•− and polarity. In the previous work, we have successfully fabricated an ER-targetable near-infrared fluorescent probe ER-P for detection of polarity.44 ER-P consists of a merocyanine moiety containing a tertiary amine as electron donor and a difluoroboronate moiety as electron acceptor. Due to the intramolecular charge transfer (ICT), the fluorescence intensity of ER-P at 800 nm decreases seriously along with increasing polarity of the media, which can indicate the polarity. Synchronously, to achieve the imaging of O2•− in live tissues, an ideal O2•−-responsive fluorescent probe with instantaneous response, high fluorescence quantum yield and long emission wavelength should be presented. Thus, we herein first developed a new ER-targetable fluorogenic probe termed ER-NAPC for detection of O2•−. As shown in Scheme 1a, ERNAPC consists of 1,8-naphthalimide (a potent fluorophore), caffeic acid group (the O2•− recognition unit), and methyl sulphonamide (ER-targetable moiety). The caffeic acid group in ER-NAPC can react with O2•− instantaneously, and is oxidized from pyrocatechol to benzoquinone, which will result in an intense fluorescence resonance energy transfer (FRET) and emit strong fluorescence of naphthalimide moiety. Thus, after reaction with O2•−, ER-NAPC will exhibit obviously increased fluorescence quantum yield. In addition, the imino group and amide in ER-NAPC form the donor-accepter system, rendering long emission wavelength, which is beneficial to tissue imaging. Because ER-NAPC and ER-P display distinguishable excitation and emission spectra (405/545 nm for ER-NAPC and 633/800 nm for ER-P), we achieved the simultaneous fluorescence visualization of O2•− and polarity during ER stress by utilizing ER-NAPC and ER-P with spectral distinguishable imaging method (Scheme 1b). Furthermore, this dual-color imaging method was utilized to simultaneous fluorescence imaging of O2•− and polarity in normal and diabetic myocardial tissues. EXPERIMENTAL SECTION Materials and General Methods. Unless otherwise stated, all reagents were purchased from commercial suppliers and used without further purification. The solvents were purified by conventional methods before use. ER-Tracker Red was
purchased from Invitrogen (USA). 3-(4, 5-dimethylthiazol-2yl) 2, 5-diphenyl tetrazolium bromide (MTT), tunicamycin (Tm), thapsigargin (Tg) and streptozotocin (STZ) were purchased from Sigma. 4-hydroxy-2,2,6,6-tetramethylpiperidineN-oxyl (TEMPO) was purchased from J&K Chemical. Superoxide dismutase (SOD) was purchased from solarbio. Silica gel (200-300 mesh) used for flash column chromatography was purchased from Qingdao Haiyang Chemical Co., Ltd. 1H NMR and 13C NMR spectra were determined by 300 MHz and 75 (or 100) MHz using Bruker NMR spectrometers. The mass spectra were obtained by Bruker maxis ultra-high resolutionTOF MS system. The fluorescence spectra measurements were performed using FLS-980 Edinburgh, Hitachi F-4600 and Varian Cary Eclipse fluorescence spectrophotometer. The adult KM mice (female, 6-8 week-old, 20±2 g) were purchased from the laboratory animal center of Shandong University (Jinan, China). All animal experiments were conducted at the laboratory of Shandong Normal University in compliance with the Guidelines of Shandong Normal University for the Care and Use of Laboratory Animals. Confocal fluorescence imaging in cells and in mice were performed with Leica TCS SP8 (one-photon) or Zeiss LSM 880 NLO (two-photon) Confocal Laser Scanning Microscope. The laser power of confocal imaging is 5.0 mW for 405, and 15 mW for 561 and 633 nm laser. The two-photon excitation wavelength is 800 nm. The cardiomyocyte cells (H9c2) and human hepatoma cells (HepG2) were purchased from Cell Bank of the Chinese Academy of Sciences (Shanghai, China). Synthesis of compound ER-NapNH2. Under argon atmosphere, compound ER-NapBr (474 mg, 1.0 mmol), ethylenediamine (600 mg, 10 mmol) and triethylamine (0.50 mL) were successively added to the stirred solution of 2-methoxyethanol (10 mL) in a round-bottomed flask. After heating at 100 °C for 10 h, the mixture was cooled to room temperature and poured into diethyl ether. The resulting precipitate was filtered and purified by silica gel chromatography with CH2Cl2:CH3OH (5:1) as the eluent to yield ER-NapNH2 as a yellow solid (230 mg, 50%). 1H NMR (300 MHz, d6-DMSO) δ(ppm): 2.263 (s, 3H), 2.645 (s, 2H), 2.921 (t, J=4.71 Hz, 2H), 3.027 (t, J=5.4 Hz, 2H), 3.407 (d, J=4.8 Hz, 2H), 4.063 (t, J=4.8 Hz, 2H), 6.765 (d, J=6.6 Hz, 1H), 7.240 (d, J=6.0 Hz, 2H), 7.592-7.653
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Analytical Chemistry (m, 3H), 7.854 (s, 1H), 8.174 (d, J=6.3 Hz, 1H), 8.345 (d, J=5.4 Hz, 1H), 8.700 (d, J=6.3 Hz, 1H). 13C NMR (75 MHz, d6-DMSO) δ(ppm): 21.3, 46.4, 58.5, 60.5, 74.4, 104.2, 108.1, 120.6, 122.2, 124.6, 126.8, 129.1, 129.9, 130.9, 134.6, 138.1, 142.9, 151.3, 163.4, 164.3. HRMS (ESI) m/z calcd. for C23H24N4O4S [M+H+] 453.1591, found 453.1617. Synthesis of ER-NAPC. Under argon atmosphere, caffeic acid (180 mg, 1.0 mmol), N-hydroxybenzotrizole (HOBT, 135 mg, 1.0 mmol) and 1-ethyl-3-(3-dimethylaminopropyl) carbodiimide hydrochloride (EDC, 192 mg, 1.0 mmol) were dissolved in 2.0 mL dimethyl formamide and 8.0 mL dichloromethane. The mixture were stirred at 0 °C for 30 min, then compound ER-NapNH2 (452 mg, 1.0 mmol) dissolved in 2.0 mL dimethyl formamide was added to the mixture. All the solution reacted at 25 °C for 24 h. The resulting mixture was concentrated and purified by silica gel chromatography with CH2Cl2:CH3OH (10:1) as the eluent to yield ER-NAPC as a yellow solid (250 mg, 40%). 1H NMR (300 MHz, d6-DMSO) δ(ppm): 1.608-1.678 (m, 2H), 1.970-2.032 (m, 2H), 2.262 (s, 3H), 3.031-3.044 (m, 2H), 4.079 (t, J=5.1 Hz, 2H), 5.321 (s, 1H), 6.294 (d, J=12 Hz, 1H), 6.367 (d, J=12 Hz, 1H), 6.776 (d, J=6.0 Hz, 1H), 6.846-6.893 (m, 2H), 7.061 (s, 1H), 7.237 (d, J=6.0 Hz, 2H), 7.330 (d, J=12 Hz, 1H), 7.506 (d, J=12 Hz, 2H), 7.606 (d, J=6.0 Hz, 2H), 8.248 (d, J=6.0 Hz, 1H), 8.411 (d, J=5.4 Hz, 1H), 8.651 (d, J=6.0 Hz, 1H), 9.169 (s, 2H). 13C NMR (100 MHz, d6-DMSO) δ(ppm): 21.34, 29.50, 29.54, 37.97, 43.41, 104.15, 108.36, 114.32, 116.22, 118.54, 120.56, 121.02, 122.36, 124.80, 126.71, 126.84, 128.00, 128.23, 128.85, 129.92, 130.11, 131.11, 134.61, 138.03, 140.06, 142.89, 146.01, 147.90, 151.00, 163.39, 164.28, 166.83. HRMS (ESI) m/z calcd. for C32H30N4O7S [M-H-] 613.1751, found 613.1672. Preparation of ROS and other active species. O2•− was prepared by dissolving KO2 in DMSO solution. The concentration of O2•− was determined by various concentrations of KO2; Tert-butyl hydroperoxide (TBHP) was delivered from 5.0 % aqueous solutions; NaOCl solution was diluted appropriately in 0.1 M NaOH aq. The concentration of OCl− was determined based on the molar extinction coefficient at 292 nm (350 M−1 cm−1); Hydrogen peroxide (H2O2) was diluted appropriately in water. The concentration of H2O2 was determined based on the molar extinction coefficient at 240 nm (43.6 M−1 cm−1); Hydroxyl radical (•OH) was produced by Fenton reaction (Fe2+/H2O2=1:10), and the concentration of • OH was equal to the Fe(II) concentration; 1O2 was generated by the addition of NaOCl and H2O2; Peroxynitrite (ONOO−) was chemically provided by H2O2 and NaNO2. The concentration of ONOO− was estimated by using an extinction coefficient of 1670 M-1 cm-1 (302 nm); The solutions of metal ions were prepared from chlorizated salts which were dissolved in deionized water. Determination of the detection limit. The detection limit was calculation based on the fluorescence titration of ERNAPC in the presence of O2•−. The fluorescence intensity of ER-NAPC was measured by three times and standard deviation of the blank measurement was achieved. The detection limit was calculated by the following equation: Detection limit = 3σ/k, where σ is the standard deviation of the blank measurement, k is the slope between the fluorescence emission intensity (I545 nm) versus different O2•− concentrations.
Determination of the relative fluorescence quantum yield. The parameter was obtained according to a previous report.51 Cell incubation and mice culture. HepG2 and H9c2 cells were cultured in Dulbecco's modified Eagle's medium (DMEM, Invitrogen) supplemented with 10 % fetal bovine serum (Invitrogen), 1.0 % penicillin and 1.0 % streptomycin. The cells were seeded in confocal culture dishes and then incubated for 24 h at 37 °C under a humidified atmosphere containing 5.0 % CO2. The Kunming mice were intraperitoneally (i.p.) injected with STZ freshly dissolved in 0.01 mol/L citrate buffer (pH 4.5) at a dose of 150 mg/kg body weight after overnight fasting. At 72 h after STZ injection, the blood glucose level of mice was detected with portable glucose meter (Roche Diagnostics Corporation). The diabetes of mouse was confirmed by the presence of hyperglycemia (blood glucose level ≥ 16.7 mmol/L). Since then, the mice were divided into three groups: control group, diabetic group (oral administration of PBS), treated diabetic group (oral administration of metformin, 150 mg/kg twice a day). After 10 days, all the mice were i.p. injected with ER-NAPC (10 µM, 100 µL) and ER-P (50 µM, 100 µL) for 40 min. For the scavenging experiment, the diabetic mice were i.p. injected with TEMPO (10 mM, 200 µL) before the probes were loaded. Then the mice were anesthetized with chloral hydrate (i.p., 400 mg/kg). Subsequently, mice were sacrificed to surgically harvest the hearts that were immediately placed in ice-cold PBS buffer. Then the myocardial tissue was directly imaged with two-photon confocal laser scanning microscopy with 800 nm laser (for ER-NAPC) and one-photon 633 nm laser (for ER-P) simultaneously. Procedure for fluorescence measurement. ER-NAPC was dissolved in dimethyl sulfoxide (DMSO) to produce a stock solution (0.1 mM). The solutions was diluted in PBS buffer (5.0 mM, pH 7.4, containing 10 % DMSO) to the lowest concentration of 1.0 µM. The molar extinction coefficient ε was calculated according to the Beer-Lambert's law equation A=εbc, where A is absorbance, b is the absorption path length (1.0 cm), c is the concentration. Different concentrations of O2•− or appropriate amounts of biologically relevant analytes were added to separate portions of the solution and mixed thoroughly with 1.0 µM ER-NAPC. FLS-980 Edinburgh fluorescence spectrometer was used to acquire the fluorescence spectra. The slit width was set to 3.0 nm. For the fluorescence stability assays, fluorescence intensity at 545 nm was collected in Varian Cary Eclipse fluorescence spectrophotometer immediately upon addition of 10 µM of O2•− to a solution of ERNAPC (1.0 µM). Hitachi F-4600 fluorescence spectrophotometer was used to detect the fluorescence response of ER-NAPC to O2•− at different pH values. RESULTS AND DISCUSSION Synthesis of probe ER-NAPC. The new ER-targetable O2•−-responsive fluorogenic probe ER-NAPC was readily synthesized in two steps as illustrated in Scheme S1. ER-NapBr has been synthesized and reported by our previous work.52 Reaction of compound ER-NapBr and ethylenediamine produced ER-NapNH2. ER-NAPC was obtained from ERNapNH2 via a typical amidation reaction with caffeic acid in anhydrous DMF and CH2Cl2. The final structures of ERNapNH2 and ER-NAPC were well characterized with 1H NMR, 13C NMR and HRMS.
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Figure 1. The spectral response of ER-NAPC to O2•− in PBS (pH 7.4, 5.0 mM, 10 % DMSO). (a) The normalized absorption spectra of ER-NAPC (1.0 µM) in the absence or presence of O2•− (10 µM). (b) The normalized fluorescence spectra of solvent or ERNAPC (1.0 µM) under different conditions. (c) The fluorescence spectra of ER-NAPC (1.0 µM) in presence of different concentrations of O2•− (0-25 µM). (d) The linear relationship of fluorescence intensity at 545 nm and O2•− (0-10 µM). Ex=400 nm.
The spectral response of probe ER-NAPC to O2•−. We first test whether ER-NAPC can respond to O2•− under physiological condition (pH 7.4, 5.0 mM PBS) by evaluating the absorption and fluorescence of ER-NAPC in the presence or absence of O2•−. As shown in Figure 1a, the probe ER-NAPC has two absorption maxima at about 327 nm (ε: 6.4x104 M−1 cm−1) and 460 nm (ε: 4.8x104 M−1 cm−1), which should be assigned to caffeic acid and naphthalimide moieties, respectively. After reacted with O2•−, the absorption maximum at these two wavelengths displayed slight increase. Concomitantly, compared with ER-NAPC alone, a significantly enhanced fluorescence signal at 545 nm (Figure 1b) appeared upon addition of O2•− because the caffeic acid was instantaneously oxidized to benzoquinone and intense FRET occurred, thereby demonstrating that ER-NAPC is a very sensitive O2•−responsive probe. Meanwhile, when O2•− was first scavenged with the universal free-radical scavenger TEMPO (10 mM), the fluorescence enhancement of ER-NAPC was almost abolished. Furthermore, ER-NAPC showed obvious turn-on fluorescence response to xanthine/xanthine oxidase (XA/XO) system that is another source of O2•−. And the fluorescence was also inhibited once XA/XO was pretreated with SOD (Figure S1). Then, we investigated the fluorescence response ability of ER-NAPC to different concentration of O2•− under physiological condition in detail. As shown in Figure 1c, with the rise of O2•−, the fluorescence spectra of ER-NAPC enhanced dramatically, and the fluorescence intensity at 545 nm increased gradually (Figure S2). The fluorescence intensity of ER-NAPC at 545 nm fits linear relationship equation F=1674.85[O2•−]+3906.39 with O2•− concentration at 0-10 µM with a detection limit of 130 nM (Figure 1d), demonstrating that ER-NAPC can detect the O2•− in live cells.[20, 53-55] And the relative fluorescence quantum yield increased from 0.06 to 0.39 in the absence and presence of O2•−. The above data verified that our design strategy effectively improved the sensitivity of ER-NAPC because of increase in fluorescence quantum yield. And upon reaction with O2•−, ER-NAPC displayed a relative long emission wavelength at 545 nm, which is prone
to tissue imaging. These results indicated ER-NAPC is high sensitive to O2•− and possesses potential ability for quantitative determination of O2•− concentrations in a large range. Selectivity and stability of ER-NAPC to O2•−. Next, The selectivity of probe ER-NAPC for O2•− over other potential interfering agents under biological conditions was investigated by fluorescence spectroscopy. We detected the fluorescence spectra of ER-NAPC in the presence of various ROS and metal ions. After addition of these analytes, the fluorescence of ER-NAPC showed almost no changes compared to that of ERNAPC alone. In sharp contrast, the fluorescence of ER-NAPC exhibited significant enhancement after addition of O2•− (Figure 2a and 2b). In addition, Figure S3 demonstrated that ERNAPC can well respond to O2•− under wide physiological condition (pH 6.0-8.0). Furthermore, the probe ER-NAPC alone and the reaction product of ER-NAPC with O2•− were stable (Figure S4). Therefore, all these data demonstrated that ERNAPC displayed excellent selectivity for O2•− over other species and had favorable pH- and photostability, which may be powerful for detection of O2•− in complex biological system.
Figure 2. The fluorescence response of ER-NAPC to various interfering species in PBS (pH 7.4, 5.0 mM, 10 % DMSO). (a) The fluorescence spectra of ER-NAPC (1.0 µM) with various analytes. (b) The fluorescence intensity ratios (F/F0) of ER-NAPC at 545 nm for various analytes. F0 indicates the blank fluorescence of ER-NAPC alone, and F represents the fluorescence of ERNAPC in the presence of corresponding analytes. 1: Solvent control; 2: Probe blank; 3: H2O2, 10 mM; 4: OCl−, 100 µM; 5: TBHP, 100 µM; 6: ONOO−, 100 µM; 7: 1O2, 100 µM; 8: •OH, 100 µM; 9: Na+, 10 mM: 10: K+: 10 mM; 11: Zn2+, 0.5 mM; 12: Cu2+, 100 µM; 13: Fe3+, 100 µM; 14: Al3+, 100 µM; 15: Mn2+, 100 µM; 16: Ca2+, 0.5 mM; 17: Mg2+, 0.5 mM; 18: O2˙¯, 10 µM. Ex=400 nm.
Figure 3. Colocalization fluorescence images of H9c2 cells stained with ER-NAPC and ER-Tracker Red after induced with high glucose. (a) The fluorescence image from ER-NAPC (1.0 µM, Ex=405 nm, collected 450-600 nm). (b) The fluorescence image from ER-Tracker Red (500 nM, Ex=561 nm, collected 580630 nm). (c) The overlay image of a and b. (d) Intensity correlation plot of stain ER-NAPC and ER-Tracker Red. Scale bar: 50 µm.
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Analytical Chemistry
Figure 4. (a) The time-dependent fluorescence imaging of H9c2 cells incubated with ER-NAPC during ER stress. (b) The output of normalized average fluorescence intensity from a. The fluorescence images of H9c2 cells incubated with ER-NAPC (1.0 µM) for 30 min then treated with 5.0 µg/mL Tm. Ex=405 nm, Em=450-600 nm. Scale bar: 100 µm.
Fluorescence imaging of O2•− in live cells with ER-NAPC. With this excellent probe in hand, we next intended to test the application of ER-NAPC in live cells fluorescence imaging. Firstly, we performed standard MTT assays to evaluate the cytotoxicity of ER-NAPC in live cells. The data in Figure S5 showed that ER-NAPC exhibits very low cytotoxicity. To start with, H9c2 cardiomyocyte cells were incubated with high glucose (25 mM) for 24 h, which is widely considered to induce production of ROS and ER stress.56 After incubated with ER-NAPC, the H9c2 cells were imaged with confocal fluorescence microscope. Obviously, these H9c2 cells emitted bright green fluorescence, indicating the production of O2•−. And the green fluorescence vanished when the cells pretreated with TEMPO or SOD (Figure S6), verifying the specificity of ERNAPC to O2•−. Moreover, the photostability of ER-NAPC had been investigated in live H9c2 cells shown in Figure S7. The fluorescent intensity of ER-NAPC showed just 10 % reduction under 5 min continuous irradiation, suggesting that the probe had excellent photostability and leakage didn’t occur during experimentation. Additionally, the high glucose stimulated H9c2 cells were incubated with ER-NAPC and ER-Tracker Red (a commercial ER dye) for colocalization experiment. As shown in Figure 3, the results suggested that the green fluorescence of ER-NAPC overlapped well with the red fluorescence of ER-Tracker Red (Figure 3c), with a high colocalization coefficient of 0.92. Further colocalization experiments implied that ER-NAPC rarely entered into mitochondria, lysosomes
and Golgi apparatus of H9c2 cells and can also accumulated into ER of HepG2 cells (Figure S8 and S9). All the above data illustrated that ER-NAPC is membrane-permeable and can solely accumulate into ER to detect O2•− in live cells. When cells undergo ER stress, ROS will produce. And the generated ROS signalling will contribute to aggravating oxidative stress and causing further ER stress, which will form vicious cycle and underlie many ER stress associated diseases.57 To further explore the bioapplication of ER-NAPC, we want to utilize ER-NAPC to track the production of endogenous O2•− under ER stress. After incubated with ER-NAPC (1.0 µM) for 30 min, H9c2 cells were stimulated with tunicamycin (Tm, 5.0 µg/mL) that is an inhibitor of protein N-glycosylation, and can trigger ER stress.58 The time-dependent fluorescence images of H9c2 cells were exhibited in Figure 4a. It showed that the fluorescence intensity of ER-NAPC rised obviously (Figure 4b), indicating the production of O2•− within ER accompying ER stress. Similarly, the level of O2•− will increase (Figure S10) after treated with thapsigargin (Tg), an inhibitor of the ubiquitous ER Ca2+-ATPases in mammalian cells, which can also cause ER stress.59 A further experiment was performed by adding Tm to HepG2 cells, displaying the gradual rise of O2•− concentration (Figure S11). The data manifested that during ER stress, O2•− can be generated. The level fluctuations of O2•− under such conditions can be monitored by ER-NAPC, which confirmed that ER-NAPC is capable of real-time imaging endogenous O2•− in living cells.
Figure 5. (a) The confocal fluorescence images of H9c2 cells stained simultaneously with ER-NAPC (1.0 µM) and ER-P (5.0 µM) in the presence of Tm (5.0 µg/mL) at different time. The first row (green channel) was fluorescence images for ER-NAPC collected 450-600 nm by the excitation at 405 nm. The second row (red channel) was fluorescence images for ER-P collected 700-800 nm by the excitation at 633 nm. The third row was bright-field images. Scale bar: 75 µm. (b) The output of normalized average fluorescence intensity from a.
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Figure 6. Confocal fluorescence imaging of endogenous O2•− and polarity in myocardial tissues. The green channel represented the two-photon fluorescence images from ER-NAPC (10 µM, Ex=800, collected 500-600 nm). The red channel represented the onephoton fluorescence images from ER-P (50 µM, Ex=633, collected 700-750 nm). (a-b) The selected fluorescence images of normal myocardial tissue. (c-f) The selected fluorescence images of diabetic myocardial tissue. (e-f) The selected fluorescence images of Metf-treated diabetic myocardial tissue. (a’-f’) The 3D stack images of corresponding myocardial tissue. Scale bar: 50 µm.
Simultaneous fluorescence imaging of O2•− and polarity in live cells with ER-NAPC and ER-P. Except for production of ROS and oxidative stress, ER stress will cause dysfunction of protein secretion and modification, and ROSderived oxidation of proteins might cause changes of the hydrophilic and hydrophobic domains, thus presumably affecting the ER polarity environment. To further real-timely visualize the fluctuation of endogenous O2•− and change of polarity, we combined ER-NAPC with a polarity-sensitive fluorescent probe ER-P44 for simultaneous fluorescence imaging in H9c2 cells stimulated with Tm. As expected, during incubation with Tm (5.0 µg/mL) within 70 min, H9c2 cells stained with ERNAPC displayed a successive increment of the green fluorescence (Figure 5, green channel), indicating the rise of endogenous O2•− contents within ER. Meanwhile, ER-P exhibited reduced red fluorescence (Figure 5, red channel), which implied that the increase of polarity in ER. Further experiments in HepG2 cells obtained the same results that O2•− level and polarity will synergistically rise during ER stress induce by Tm (Figure S12). All these data confirmed the synergistic effect of endogenous O2•− and polarity. By utilizing ER-NAPC and ER-P, we achieved the simultaneous fluorescence imaging of these two parameters. Simultaneous fluorescence imaging of O2•− and polarity in myocardial tissues with ER-NAPC and ER-P. Previous work reported that the myocardial superoxide level will be overproduced,19 however, it’s still elusive whether polarity will change. Having established the ability of ER-NAPC and ER-P to detect O2•− and polarity in the live cells simultaneously, we next investigated their capabilities to determinate O2•−
and polarity in STZ-induced diabetic myocardial tissues.60 Considering the fluorophore 1,8-naphthalimide in ER-NAPC is an ideal two-photon dye,61,62 we therefore took advantage of two-photo microscope for ER-NAPC. The fluorescence images at different depths in Figure 6 demonstrated that normal myocardial tissue displayed faint green fluorescence from ERNAPC and high red fluorescence from ER-P (Figure 6a and 6b), implying the low concentration of O2•− and low polarity environment. However, in diabetic myocardial tissue, ERNAPC showed dramatically elevated fluorescence (Figure 6c), which illustrated that O2•− is overproduced. Meanwhile, ER-P emitted weak fluorescence (Figure 6d), suggesting the increase of polarity. Additionally, when the diabetic mice were orally treated with metformin (Metf) that is a biguanide derivate used as an oral hypoglycaemic drug in diabetics, which has protective effects on streptozotocin-diabetic rats,1 the O2•− level is reduced and the polarity decreased to some extent (Figure 6e and 6f). These data prompted that O2•− level and polarity will increased in heart tissue of mice with DCM and hypoglycaemic drug Metf can partly recover the level of O2•− and polarity. Additionally, we also tested the selectivity of ER-NAPC to O2•− in diabetic myocardial tissue. As shown in Figure S13, after preincubated with TEMPO, diabetic myocardial tissue exhibited faint fluorescence, manifesting the decrease of O2•−. Taken together, these data indicated that ER-NAPC and ER-P can simultaneously and solely visualize O2•− and polarity respectively in myocardial tissues of normal and diabetic mice. CONCLUSIONS
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In conclusion, we have developed a new method for simultaneous fluorescence visualization of ER O2•− and polarity in myocardial cells and tissues. This method used a new ERtargetable fluorogenic probe termed ER-NAPC for sensitive and selective imaging of O2•−. Due to the distinguishable spectra of ER-NAPC and our reported polarity-responsive fluorescent probe ER-P, we accomplished the simultaneous fluorescence visualization of O2•− and polarity during ER stress in myocardial cells by utilizing ER-NAPC and ER-P with spectral distinguishable imaging method. The imaging results demonstrated that O2•− and polarity will synergistically increase under ER stress. Furthermore, the endogenous O2•− concentration and polarity difference in myocardial tissues of normal and diabetic mice as well as treated diabetic mice was determinated with this dual-color imaging method. It was found that elevated O2•− level and polarity appeared in myocardial tissue of diabetic mice. We expect that this method for simultaneous imaging of O2•− and polarity will help to more accurately study the occurrence and development of diabetic cardiac disease. Meanwhile, the presented dual-color imaging strategy may offer new direction for exploring the synergetic variation of different parameters during other diseases.
ASSOCIATED CONTENT Supporting Information The Supporting Information is available free of charge on the ACS Publications website. Synthetic route; photophysical data; cell data (PDF)
AUTHOR INFORMATION ORCID Bo Tang: 0000-0002-8712-7025
Notes The authors declare no competing financial interest.
ACKNOWLEDGMENT This work was supported by the National Natural Science Foundation of China (21535004, 91753111, 21390411, 21675105, 21475079), National Major Scientific and Technological Special Project for “Significant New Drugs Development” (2017ZX09301030004) and the Natural Science Foundation of Shandong Province of China (ZR2017ZC0225).
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